Crystal radio

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This article is about unpowered radio receivers. For crystal-controlled oscillators (as used in radios), see Crystal oscillator.

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"Crystal set" redirects here. For the Australian rock band, see The Crystal Set.
File:Vintage Arrow Germanium Crystal Radio (23708349181).jpg
1970s-era crystal radio marketed to children. The earphone is on left. The antenna wire, right, has a clip to attach to metal objects such as a bedspring, which serve as an additional antenna to improve reception.

A crystal radio receiver, also called a crystal set or cat's whisker receiver, is a very simple radio receiver, popular in the early days of radio. It needs no other power source but that received solely from the power of radio waves received by a wire antenna. It gets its name from its most important component, known as a crystal detector, originally made from a piece of crystalline mineral such as galena.[1] This component is now called a diode.

Crystal radios are the simplest type of radio receiver[2] and can be made with a few inexpensive parts, such as a wire for an antenna, a coil of copper wire for adjustment, a capacitor, a crystal detector, and earphones.[3] Crystal radios are distinct from ordinary radios as they are passive receivers, while other radios use a separate source of electric power such as a battery or the mains power to amplify the weak radio signal so as to make it louder. Thus, crystal sets produce rather weak sound and must be listened to with sensitive earphones, and can only receive stations within a limited range.[4]

The rectifying property of crystals was discovered in 1874 by Karl Ferdinand Braun,[5][6][7] and crystal detectors were developed and applied to radio receivers in 1904 by Jagadish Chandra Bose,[8][9] G. W. Pickard[10] and others. Crystal radios were the first widely used type of radio receiver,[11] and the main type used during the wireless telegraphy era.[12] Sold and homemade by the millions, the inexpensive and reliable crystal radio was a major driving force in the introduction of radio to the public, contributing to the development of radio as an entertainment medium with the beginning of radio broadcasting around 1920.[13]

Around 1920, crystal sets were superseded by the first amplifying receivers, which used vacuum tubes, after which crystal sets became obsolete for commercial use.[11] They continued to be built by hobbyists, youth groups, and the Boy Scouts[14] however, as a way of learning about the technology of radio. Today they are still sold as educational devices, and there are groups of enthusiasts devoted to their construction[15][16][17][18][19]

Crystal radios receive amplitude modulated (AM) signals, and can be designed to receive almost any radio frequency band, but most receive the AM broadcast band.[20] A few receive shortwave bands, but strong signals are required. The first crystal sets received wireless telegraphy signals broadcast by spark-gap transmitters at frequencies as low as 20 kHz.[21][22]

History

A family listening to a crystal radio in the 1920s
Greenleaf Whittier Pickard's US Patent 836,531 "Means for receiving intelligence communicated by electric waves" diagram
Radio receiver, Basel, Switzerland, 1914
NBS Circular 120 Home Crystal Radio Project
File:Crystal radio backup on SS Jeremiah O'Brien.agr.jpg
Crystal radio used as a backup receiver on a World War II Liberty ship

Crystal radio was invented by a long, partly obscure chain of discoveries in the late 19th century that gradually evolved into more and more practical radio receivers in the early 20th century. The earliest practical use of crystal radio was to receive Morse code radio signals transmitted, from spark-gap transmitters, by early amateur radio experimenters. As electronics evolved, the ability to send voice signals by radio caused a technological explosion in the years around 1920 that evolved into today's radio broadcasting industry.

Early years

Early radio telegraphy used spark gap and arc transmitters as well as high-frequency alternators running at radio frequencies. The coherer was the first means of detecting a radio signal. These, however, lacked the sensitivity to detect weak signals.

In the early 20th century, various researchers discovered that certain metallic minerals, such as galena, could be used to detect radio signals.[23][24]

In 1901, Bose filed for a U.S. patent for "A Device for Detecting Electrical Disturbances" that mentioned the use of a galena crystal; this was granted in 1904, #755840.[25] The device depended on the large variation of a semiconductor's conductance with temperature; today we would call his invention a bolometer.[citation needed] Bose's patent is frequently, but erroneously, cited as a type of rectifying detector. On August 30, 1906, Greenleaf Whittier Pickard filed a patent for a silicon crystal detector, which was granted on November 20, 1906.[26] Pickard's detector was revolutionary in that he found that a fine pointed wire known as a "cat's whisker", in delicate contact with a mineral, produced the best semiconductor effect (that of rectification).

A crystal detector includes a crystal, a special thin wire that contacts the crystal, and the stand that holds those components in place. The most common crystal used is a small piece of galena; pyrite was also often used, as it was a more easily adjusted and stable mineral, and quite sufficient for urban signal strengths. Several other minerals also performed well as detectors. Another benefit of crystals was that they could demodulate amplitude modulated signals.[citation needed] This device brought radiotelephones and voice broadcast to a public audience. Crystal sets represented an inexpensive and technologically simple method of receiving these signals at a time when the embryonic radio broadcasting industry was beginning to grow.

1920s and 1930s

In 1922 the (then named) US Bureau of Standards released a publication entitled Construction and Operation of a Simple Homemade Radio Receiving Outfit.[27] This article showed how almost any family having a member who was handy with simple tools could make a radio and tune into weather, crop prices, time, news and the opera. This design was significant in bringing radio to the general public. NBS followed that with a more selective two-circuit version, Construction and Operation of a Two-Circuit Radio Receiving Equipment With Crystal Detector, which was published the same year [28] and is still frequently built by enthusiasts today.

In the beginning of the 20th century, radio had little commercial use, and radio experimentation was a hobby for many people.[29] Some historians consider the autumn of 1920 to be the beginning of commercial radio broadcasting for entertainment purposes. Pittsburgh station KDKA, owned by Westinghouse, received its license from the United States Department of Commerce just in time to broadcast the Harding-Cox presidential election returns. In addition to reporting on special events, broadcasts to farmers of crop price reports were an important public service in the early days of radio.

In 1921, factory-made radios were very expensive. Since less-affluent families could not afford to own one, newspapers and magazines carried articles on how to build a crystal radio with common household items. To minimize the cost, many of the plans suggested winding the tuning coil on empty pasteboard containers such as oatmeal boxes, which became a common foundation for homemade radios.

Crystodyne

In early 1920s Russia, Oleg Losev was experimenting with applying voltage biases to various kinds of crystals for manufacture of radio detectors. The result was astonishing: with a zincite (zinc oxide) crystal he gained amplification.[30][31][32] This was negative resistance phenomenon, decades before the development of the tunnel diode. After the first experiments, Losev built regenerative and superheterodyne receivers, and even transmitters.

A crystodyne could be produced in primitive conditions; it can be made in a rural forge, unlike vacuum tubes and modern semiconductor devices. However, this discovery was not supported by authorities and soon forgotten; no device was produced in mass quantity beyond a few examples for research.

"Foxhole radios"

"Foxhole radio" used on the Italian Front in World War 2. It uses a pencil lead attached to a safety pin pressing against a razor blade for a detector.

In addition to mineral crystals, the oxide coatings of many metal surfaces act as semiconductors (detectors) capable of rectification. Crystal radios have been improvised using detectors made from rusty nails, corroded pennies, and many other common objects.

When Allied troops were halted near Anzio, Italy during the spring of 1944, powered personal radio receivers were strictly prohibited as the Germans had equipment that could detect the local oscillator signal of superheterodyne receivers. Crystal sets lack power driven local oscillators, hence they could not be detected. Some resourceful soldiers constructed "crystal" sets from discarded materials to listen to news and music. One type used a blue steel razor blade and a pencil lead for a detector. The lead point touching the semiconducting oxide coating (rust) on the blade formed a crude point-contact diode. By carefully adjusting the pencil lead on the surface of the blade, they could find sensitive spots, of iron oxide, capable of rectification. The lead of the pencil is made of graphite and clay and so it would inhibit further corrosion that would result if copper or iron wire was used in its place. Any further corrosion at the point of contact would ruin the diode effect found at that spot and further adjustment would be necessary. The sets were dubbed "foxhole radios" by the popular press, and they became part of the folklore of World War II.

In some German-occupied countries during WW2 there were widespread confiscations of radio sets from the civilian population. This led determined listeners to build their own "clandestine receivers" which frequently amounted to little more than a basic crystal set. However, anyone doing so risked imprisonment or even death if caught, and in most parts of Europe the signals from the BBC (or other allied stations) were not strong enough to be received on such a set.

Later years

While it never regained the popularity and general use that it enjoyed at its beginnings, the crystal radio circuit is still used. The Boy Scouts have kept the construction of a radio set in their program since the 1920s. A large number of prefabricated novelty items and simple kits could be found through the 1950s and 1960s, and many children with an interest in electronics built one.

Building crystal radios was a craze in the 1920s, and again in the 1950s. Recently, hobbyists have started designing and building examples of the early instruments. Much effort goes into the visual appearance of these sets as well as their performance. Annual crystal radio 'DX' contests (long distance reception) and building contests allow these set owners to compete with each other and form a community of interest in the subject.

Design

Block diagram of a crystal radio receiver

A crystal radio can be thought of as a radio receiver reduced to its essentials.[3][33] It consists of at least these components:[20][34][35]

  • An antenna in which electric currents are induced by the radio waves.
  • A resonant circuit (tuned circuit) which serves to select the frequency of the desired radio station out of all the radio signals received by the antenna. The tuned circuit consists of a coil of wire (called an inductor) and a capacitor connected together, so as to create a circuit that resonates at the frequency of the desired station, and hence "tune" in that station. One or both of the coil or capacitor is adjustable, allowing the circuit to be tuned to different frequencies. In some circuits a capacitor is not used, as the antenna also serves as the capacitor. The tuned circuit has a resonant frequency and allows radio waves at that frequency to pass to the detector, while rejecting waves at all other frequencies. Such a circuit is also known as a bandpass filter.
  • A semiconductor crystal (detector) that demodulates the radio signal to get the audio signal (modulation). The crystal detector is a nonlinear impedance that functions as a square law detector[citation needed]. The detector's output is converted to sound by the earphone. Early sets used a cat's whisker detector, consisting of a fine wire touching the surface of a sample of crystalline mineral such as galena. It was this component that gave crystal sets their name.
  • An earphone to convert the audio signal to sound waves so they can be heard. The low power produced by a crystal receiver is insufficient to power a loudspeaker, hence earphones are used.
Pictorial diagram from 1922 showing the circuit of a crystal radio. This common circuit did not use a tuning capacitor, but used the capacitance of the antenna to form the tuned circuit with the coil. The detector might have been a piece of galena with a whisker wire in contact with it on a part of the crystal, making a diode contact

As a crystal radio has no power supply, the sound power produced by the earphone comes solely from the transmitter of the radio station being received, via the radio waves captured by the antenna.[3] The power available to a receiving antenna decreases with the square of its distance from the radio transmitter.[36] Even for a powerful commercial broadcasting station, if it is more than a few miles from the receiver the power received by the antenna is very small, typically measured in microwatts or nanowatts.[3] In modern crystal sets, signals as weak as 50 picowatts at the antenna can be heard.[37] Crystal radios can receive such weak signals without using amplification only due to the great sensitivity of human hearing,[3][38] which can detect sounds with an intensity of only 10−16 W/cm2.[39] Therefore, crystal receivers have to be designed to convert the energy from the radio waves into sound waves as efficiently as possible. Even so, they are usually only able to receive stations within distances of about 25 miles for AM broadcast stations,[40][41] although the radiotelegraphy signals used during the wireless telegraphy era could be received at hundreds of miles,[41] and crystal receivers were even used for transoceanic communication during that period.[42]

Commercial passive receiver development was abandoned with the advent of reliable vacuum tubes around 1920, and subsequent crystal radio research was primarily done by radio amateurs and hobbyists.[43] Many different circuits have been used.[2][44][45] The following sections discuss the parts of a crystal radio in greater detail.

Antenna

The antenna converts the energy in the electromagnetic radio waves to an alternating electric current in the antenna, which is connected to the tuning coil. Since in a crystal radio all the power comes from the antenna, it is important that the antenna collect as much power from the radio wave as possible. The larger an antenna, the more power it can intercept. Antennas of the type commonly used with crystal sets are most effective when their length is close to a multiple of a quarter-wavelength of the radio waves they are receiving. Since the length of the waves used with crystal radios is very long (AM broadcast band waves are 182-566 m or 597–1857 ft. long)[46] the antenna is made as long as possible,[47] from a long wire, in contrast to the whip antennas or ferrite loopstick antennas used in modern radios.

Serious crystal radio hobbyists use "inverted L" and "T" type antennas, consisting of hundreds of feet of wire suspended as high as possible between buildings or trees, with a feed wire attached in the center or at one end leading down to the receiver.[48][49] However more often random lengths of wire dangling out windows are used. A popular practice in early days (particularly among apartment dwellers) was to use existing large metal objects, such as bedsprings,[14] fire escapes, and barbed wire fences as antennas.[41][50][51]

Ground

The wire antennas used with crystal receivers are monopole antennas which develop their output voltage with respect to ground. The receiver thus requires a connection to ground (the earth) as a return circuit for the current. The ground wire was attached to a radiator, water pipe, or a metal stake driven into the ground.[52][53] In early days if an adequate ground connection could not be made a counterpoise was sometimes used.[54][55] A good ground is more important for crystal sets than it is for powered receivers, as crystal sets are designed to have a low input impedance needed to transfer power efficiently from the antenna. A low resistance ground connection (preferably below 25 Ω) is necessary because any resistance in the ground reduces available power from the antenna.[47] In contrast, modern receivers are voltage-driven devices, with high input impedance, hence little current flows in the antenna/ground circuit. Also, mains powered receivers are grounded adequately through their power cords, which are in turn attached to the earth by way of a well established ground.

Tuned circuit

The earliest crystal receiver circuit did not have a tuned circuit

The tuned circuit, consisting of a coil and a capacitor connected together, acts as a resonator, similar to a tuning fork.[56] Electric charge, induced in the antenna by the radio waves, flows rapidly back and forth between the plates of the capacitor through the coil. The circuit has a high impedance at the desired radio signal's frequency, but a low impedance at all other frequencies.[57] Hence, signals at undesired frequencies pass through the tuned circuit to ground, while the desired frequency is instead passed on to the detector (diode) and stimulates the earpiece and is heard. The frequency of the station received is the resonant frequency f of the tuned circuit, determined by the capacitance C of the capacitor and the inductance L of the coil:[58]

f = \frac {1}{ 2 \pi \sqrt {LC}} \,

By varying either the inductor (L) or the capacitance (C), the circuit can be adjusted to different frequencies. In inexpensive sets, the inductor was made variable via a spring contact pressing against the windings that could slide along the coil, thereby introducing a larger or smaller number of turns of the coil into the circuit. Thus the inductance could be varied, "tuning" the circuit to the frequencies of different radio stations.[1] Alternatively, a variable capacitor is used to tune the circuit.[59] Some modern crystal sets use a ferrite core tuning coil, in which a ferrite magnetic core is moved into and out of the coil, thereby varying the inductance by changing the magnetic permeability (this eliminated the less reliable mechanical contact).[60]

The antenna is an integral part of the tuned circuit and its reactance contributes to determining the circuit's resonant frequency. Antennas usually act as a capacitance, as antennas shorter than a quarter-wavelength have capacitive reactance.[47] Many early crystal sets did not have a tuning capacitor,[61] and relied instead on the capacitance inherent in the wire antenna (in addition to significant parasitic capacitance in the coil[62]) to form the tuned circuit with the coil.

The earliest crystal receivers did not have a tuned circuit at all, and just consisted of a crystal detector connected between the antenna and ground, with an earphone across it.[1][61] Since this circuit lacked any frequency-selective elements besides the broad resonance of the antenna, it had little ability to reject unwanted stations, so all stations within a wide band of frequencies were heard in the earphone[43] (in practice the most powerful usually drowns out the others). It was used in the earliest days of radio, when only one or two stations were within a crystal set's limited range.

Impedance matching

200px
"Two slider" crystal radio circuit.[43] and example from 1920s. The two sliding contacts on the coil allowed the impedance of the radio to be adjusted to match the antenna as the radio was tuned, resulting in stronger reception

An important principle used in crystal radio design to transfer maximum power to the earphone is impedance matching.[43][63] The maximum power is transferred from one part of a circuit to another when the impedance of one circuit is the complex conjugate of that of the other; this implies that the two circuits should have equal resistance.[1][64][65] However, in crystal sets, the impedance of the antenna-ground system (around 10-200 ohms[47]) is usually lower than the impedance of the receiver's tuned circuit (thousands of ohms at resonance),[66] and also varies depending on the quality of the ground attachment, length of the antenna, and the frequency to which the receiver is tuned.[37]

Therefore, in improved receiver circuits, in order to match the antenna impedance to the receiver's impedance, the antenna was connected across only a portion of the tuning coil's turns.[58][61] This made the tuning coil act as an impedance matching transformer (in an autotransformer connection) in addition to providing the tuning function. The antenna's low resistance was increased (transformed) by a factor equal to the square of the turns ratio (the ratio of the number of turns the antenna was connected to, to the total number of turns of the coil), to match the resistance across the tuned circuit.[65] In the "two-slider" circuit, popular during the wireless era, both the antenna and the detector circuit were attached to the coil with sliding contacts, allowing (interactive)[67] adjustment of both the resonant frequency and the turns ratio.[68][69][70] Alternatively a multiposition switch was used to select taps on the coil. These controls were adjusted until the station sounded loudest in the earphone.

Problem of selectivity

Direct-coupled circuit with impedance matching[43]

One of the drawbacks of crystal sets is that they are vulnerable to interference from stations near in frequency to the desired station; that is to say, they have low selectivity.[clarification needed][2][4][37] Often two or more stations are heard simultaneously. This is because the simple tuned circuit does not reject nearby signals well; it allows a wide band of frequencies to pass through, that is, it has a large bandwidth (low Q factor) compared to modern receivers.[4]

The crystal detector worsened the problem, because it has relatively low resistance, thus it "loaded" the tuned circuit,[clarification needed], damping the oscillations (lowering the response), and reducing its Q.[37][71] In many circuits, the selectivity was improved by connecting the detector and earphone circuit to a tap across only a fraction of the coil's turns.[43] This reduced the impedance loading of the tuned circuit, as well as improving the impedance match with the detector.[43]

Inductive coupling

Inductively-coupled circuit with impedance matching. This type was used in most quality crystal receivers
Amateur-built crystal receiver with "loose coupler" antenna transformer, Belfast, around 1914

In more sophisticated crystal receivers, the tuning coil is replaced with an adjustable air core antenna coupling transformer[1][43] which improves the selectivity by a technique called loose coupling.[61][70][72] This consists of two magnetically coupled coils of wire, one (the primary) attached to the antenna and ground and the other (the secondary) attached to the rest of the circuit. The current from the antenna creates an alternating magnetic field in the primary coil, which induced a current in the secondary coil which was then rectified and powered the earphone. Each of the coils functions as a tuned circuit; the primary coil resonated with the capacitance of the antenna (or sometimes another capacitor), and the secondary coil resonated with the tuning capacitor. Both the primary and secondary were tuned to the frequency of the station. The two circuits interacted to form a resonant transformer.

Reducing the coupling between the coils, by physically separating them so that less of the magnetic field of one intersects the other, reduces the mutual inductance, narrows the bandwidth, and results in much sharper, more selective tuning than that produced by a single tuned circuit.[61][73] However, the looser coupling also reduced the power of the signal passed to the second circuit. The transformer was made with adjustable coupling, to allow the listener to experiment with various settings to gain the best reception.

One design common in early days, called a "loose coupler", consisted of a smaller secondary coil inside a larger primary coil.[43][74] The smaller coil was mounted on a rack so it could be slid linearly in or out of the larger coil. If radio interference was encountered, the smaller coil would be slid further out of the larger, loosening the coupling, narrowing the bandwidth, and thereby rejecting the interfering signal.

The antenna coupling transformer also functioned as an impedance matching transformer, that allowed a better match of the antenna impedance to the rest of the circuit. One or both of the coils usually had several taps which could be selected with a switch, allowing adjustment of the number of turns of that transformer and hence the "turns ratio".

Coupling transformers were difficult to adjust, because the three adjustments, the tuning of the primary circuit, the tuning of the secondary circuit, and the coupling of the coils, were all interactive, and changing one affected the others.[75]

Crystal detector

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Main article: Cat's whisker detector
Galena cat's whisker detector
Germanium diode used in modern crystal radios (about 3 mm long)
How the crystal detector works. [76][77] (A) The amplitude modulated radio signal from the tuned circuit. The rapid oscillations are the radio frequency carrier wave. The audio signal (the sound) is contained in the slow variations (modulation) of the amplitude (hence the term amplitude modulation, AM) of the waves. This signal cannot be converted to sound by the earphone, because the audio excursions are the same on both sides of the axis, averaging out to zero, which would result in no net motion of the earphone's diaphragm. (B) The crystal conducts current better in one direction than the other, producing a signal whose amplitude does not average to zero but varies with the audio signal. (C) A bypass capacitor is used to remove the radio frequency carrier pulses, leaving the audio signal
Circuit with detector bias battery to improve sensitivity and buzzer to adjust cat's whisker

The crystal detector demodulates the radio frequency signal, extracting the modulation (the audio signal which represents the sound waves) from the radio frequency carrier wave. In early receivers, the detector was a cat's whisker detector consisting of a fine metal wire, the "cat's whisker", on an adjustable arm that touched a pea-sized lump of semiconducting mineral.[1][6][78] The point of contact between the wire and the crystal produced a diode effect. The cat's whisker detector was a crude Schottky diode that allowed current to flow better in one direction than in the opposite direction.[79][80] Modern crystal sets use modern semiconductor diodes.[71] The crystal functions as an envelope detector, rectifying the alternating current radio signal to a pulsing direct current, the peaks of which trace out the audio signal, so it can be converted to sound by the earphone, which is connected to the detector.[20][not in citation given][77][not in citation given] The rectified current from the detector has radio frequency pulses from the carrier frequency in it, which are blocked by the high inductive reactance and do not pass well through the coils of early date earphones. Hence, a small capacitor called a bypass capacitor is often placed across the earphone terminals; its low reactance at radio frequency bypasses these pulses around the earphone to ground.[81] In some sets the earphone cord had enough capacitance that this component could be omitted.[61]

In a cat's whisker detector only certain sites on the crystal surface functioned as rectifying junctions, and the device was very sensitive to the pressure of the crystal-wire contact, which could be disrupted by the slightest vibration.[6][82] Therefore, a usable contact point had to be found by trial and error before each use. The operator dragged the wire across the crystal surface until a radio station or "static" sounds were heard in the earphones.[83] Alternatively, some radios (circuit, right) used a battery-powered buzzer attached to the input circuit to adjust the detector.[83] The spark at the buzzer's electrical contacts served as a weak source of static, so when the detector began working, the buzzing could be heard in the earphones. The buzzer was then turned off, and the radio tuned to the desired station.

Galena (lead sulfide) was probably the most common crystal used in cat's whisker detectors,[70][82] but various other types of crystals were also used, the most common being iron pyrite (fool's gold, FeS2), silicon, molybdenite (MoS2), silicon carbide (carborundum, SiC), and a zincite-bornite (ZnO-Cu5FeS4) crystal-to-crystal junction trade-named Perikon.[38][84] Crystal radios have also been improvised from a variety of common objects, such as blue steel razor blades and lead pencils,[38][85] rusty needles,[86] and pennies[38] In these, a semiconducting layer of oxide or sulfide on the metal surface is usually responsible for the rectifying action.[38]

In modern sets, a semiconductor diode is used for the detector, which is much more reliable than a cat's whisker detector and requires no adjustments.[38][71][87] Germanium diodes (or sometimes Schottky diodes) are used instead of silicon diodes, because their lower forward voltage drop (roughly 0.3V compared to 0.6V[88]) makes them more sensitive.[71][89]

All semiconductor detectors function rather inefficiently in crystal receivers, because the low voltage input to the detector is too low to result in much difference between forward better conduction direction, and the reverse weaker conduction. To improve the sensitivity of some of the early crystal detectors, such as silicon carbide, a small forward bias voltage was applied across the detector by a battery and potentiometer.[90][not in citation given][91][not in citation given] The bias moves the diode's operating point higher on the detection curve producing more signal voltage at the expense of less signal current (higher impedance). There is a limit to the benefit that this produces, depending on the other impedances of the radio. This improved sensitivity was caused by moving the DC operating point to a more desirable voltage-current operating point (impedance) on the junction's I-V curve. The battery did not power the radio, but only provided the biasing voltage which required little power.

Earphones

Modern crystal radio with piezoelectric earphone

The requirements for earphones used in crystal sets are different from earphones used with modern audio equipment. They have to be efficient at converting the electrical signal energy to sound waves, while most modern earphones sacrifice efficiency in order to gain high fidelity reproduction of the sound.[92] In early homebuilt sets, the earphones were the most costly component.[93]

The early earphones used with wireless-era crystal sets had moving iron drivers that worked in a way similar to the horn loudspeakers of the period; modern loudspeakers use a moving-coil principle. Each earpiece contained a permanent magnet about which was a coil of wire which formed a second electromagnet. Both magnetic poles were close to a steel diaphram of the speaker. When the audio signal from the radio was passed through the electromagnet's windings, current was caused to flow in the coil which created a varying magnetic field that augmented or diminished that due to the permanent magnet. This varied the force of attraction on the diaphragm, causing it to vibrate. The vibrations of the diaphragm push and pull on the air in front of it, creating sound waves. Standard headphones used in telephone work had a low impedance, often 75 Ω, and required more current than a crystal radio could supply. Therefore, the type used with crystal set radios (and other sensitive equipment) was wound with more turns of finer wire giving it a high impedance of 2000-8000 Ω.[94][95][96]

Modern crystal sets use piezoelectric crystal earpieces, which are much more sensitive and also smaller.[92] They consist of a piezoelectric crystal with electrodes attached to each side, glued to a light diaphragm. When the audio signal from the radio set is applied to the electrodes, it causes the crystal to vibrate, vibrating the diaphragm. Crystal earphones are designed as ear buds that plug directly into the ear canal of the wearer, coupling the sound more efficiently to the eardrum. Their resistance is much higher (typically megohms) so they do not greatly "load" the tuned circuit, allowing increased selectivity of the receiver. The piezoelectric earphone's higher resistance, in parallel with its capacitance of around 9 pF, creates a filter that allows the passage of low frequencies, but blocks the higher frequencies.[97] In that case a bypass capacitor is not needed (although in practice a small one of around 0.68 to 1 nF is often used to help improve quality), but instead a 10-100 kΩ resistor must be added in parallel with the earphone's input.[98]

Although the low power produced by crystal radios is typically insufficient to drive a loudspeaker, some homemade 1960s sets have used one, with an audio transformer to match the low impedance of the speaker to the circuit.[99] Similarly, modern low-impedance (8 Ω) earphones cannot be used unmodified in crystal sets because the receiver does not produce enough current to drive them. They are sometimes used by adding an audio transformer to match their impedance with the higher impedance of the driving antenna circuit.

Use as a power source

A crystal radio tuned to a strong local transmitter can be used as a power source for a second amplified receiver of a distant station that cannot be heard without amplification.[100]:122–123

There is a long history of unsuccessful attempts and unverified claims to recover the power in the carrier of the received signal itself. Traditional crystal sets use half-wave rectifiers. As AM signals have a modulation factor of only 30% by voltage at peaks[citation needed], no more than 9% of received signal power (P = U^2/R) is actual audio information, and 91% is just rectified DC voltage. Given that the audio signal is unlikely to be at peak all the time, the ratio of energy is, in practice, even greater. Considerable effort was made to convert this DC voltage into sound energy. Some earlier attempts include a one-transistor[101] amplifier in 1966. Sometimes efforts to recover this power are confused with other efforts to produce a more efficient detection.[102] This history continues now with designs as elaborate as "inverted two-wave switching power unit".[100]:129

Gallery

Soldier listening to a crystal radio during World War I, 1914
Australian signallers using a Marconi Mk III crystal receiver, 1916.
Marconi Type 103 crystal set.
SCR-54-A crystal set used by US Signal Corps in World War I
Marconi Type 106 crystal receiver used for transatlantic communication, ca. 1921
Homemade "loose coupler" set (top), Florida, ca. 1920
Crystal radio, Germany, ca. 1924
Swedish "box" crystal radio with earphones, ca. 1925
German Heliogen brand radio showing "basket-weave" coil, 1935
Polish Detefon brand radio, 1930-1939, using a "cartridge" type crystal (top)
During the wireless telegraphy era before 1920, crystal receivers were "state of the art", and sophisticated models were produced. After 1920 crystal sets became the cheap alternative to vacuum tube radios, used in emergencies and by youth and the poor.

See also

References

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  9. Sarkar (2006) History of wireless, p.94, 291-308
  10. Lua error in package.lua at line 80: module 'strict' not found. on Stay Tuned website
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  12. crystal detectors were used in receivers in greater numbers than any other type of detector after about 1907. Lua error in package.lua at line 80: module 'strict' not found.
  13. Lua error in package.lua at line 80: module 'strict' not found.
  14. 14.0 14.1 Lua error in package.lua at line 80: module 'strict' not found.
  15. Jack Bryant (2009) Birmingham Crystal Radio Group, Birmingham, Alabama, US. Retrieved 2010-01-18.
  16. The Xtal Set Society midnightscience.com . Retrieved 2010-01-18.
  17. Darryl Boyd (2006) Stay Tuned Crystal Radio website . Retrieved 2010-01-18.
  18. Al Klase Crystal Radios, Klase's SkyWaves website . Retrieved 2010-01-18.
  19. Mike Tuggle (2003) Designing a DX crystal set Antique Wireless Association journal . Retrieved 2010-01-18.
  20. 20.0 20.1 20.2 Lua error in package.lua at line 80: module 'strict' not found.
  21. Lua error in package.lua at line 80: module 'strict' not found.
  22. Long distance transoceanic stations of the era used wavelengths of 10,000 to 20,000 meters, correstponding to frequencies of 15 to 30 kHz.Lua error in package.lua at line 80: module 'strict' not found.
  23. In May 1901, Karl Ferdinand Braun of Strasbourg used psilomelane, a manganese oxide ore, as an R.F. detector: Ferdinand Braun (December 27, 1906) "Ein neuer Wellenanzeiger (Unipolar-Detektor)" (A new R.F. detector (one-way detector)), Elektrotechnische Zeitschrift, 27 (52) : 1199-1200. From page 1119:
    "Im Mai 1901 habe ich einige Versuche im Laboratorium gemacht und dabei gefunden, daß in der Tat ein Fernhörer, der in einen aus Psilomelan und Elementen bestehenden Kreis eingeschaltet war, deutliche und scharfe Laute gab, wenn dem Kreise schwache schnelle Schwingungen zugeführt wurden. Das Ergebnis wurde nachgeprüft, und zwar mit überraschend gutem Erfolg, an den Stationen für drahtlose Telegraphie, an welchen zu dieser Zeit auf den Straßburger Forts von der Königlichen Preußischen Luftschiffer-Abteilung unter Leitung des Hauptmannes von Sigsfeld gearbeitet wurde."
    (In May 1901, I did some experiments in the lab and thereby found that in fact an earphone, which was connected in a circuit consisting of psilomelane and batteries, produced clear and strong sounds when weak, rapid oscillations were introduced to the circuit. The result was verified -- and indeed with surprising success -- at the stations for wireless telegraphy, which, at this time, were operated at the Strasbourg forts by the Royal Prussian Airship-Department under the direction of Capt. von Sigsfeld.)
    Braun also states that he had been researching the conductive properties of semiconductors since 1874. See: Braun, F. (1874) "Ueber die Stromleitung durch Schwefelmetalle" (On current conduction through metal sulfides), Annalen der Physik und Chemie, 153 (4) : 556-563. In these experiments, Braun applied a cat's whisker to various semiconducting crystals and observed that current flowed in only one direction.
    Braun patented an R.F. detector in 1906. See: (Ferdinand Braun), "Wellenempfindliche Kontaktstelle" (R.F. sensitive contact), Deutsches Reichspatent DE 178,871, (filed: Feb. 18, 1906 ; issued: Oct. 22, 1906). Available on-line at: Foundation for German communication and related technologies.
  24. Other inventors who patented crystal R.F. detectors:
    • In 1906, Henry Harrison Chase Dunwoody (1843-1933) of Washington, D.C., a retired general of the US Army's Signal Corps, received a patent for a carborundum R.F. detector. See: Dunwoody, Henry H. C. "Wireless-telegraph system," U. S. patent 837,616 (filed: March 23, 1906 ; issued: December 4, 1906).
    • In 1907, Louis Winslow Austin received a patent for his R.F. detector consisting of tellurium and silicon. See: Louis W. Austin, "Receiver," US patent 846,081 (filed: Oct. 27, 1906 ; issued: March 5, 1907).
    • In 1908, Wichi Torikata of the Imperial Japanese Electrotechnical Laboratory of the Ministry of Communications in Tokyo was granted Japanese patent 15,345 for the “Koseki” detector, consisting of crystals of zincite and bornite.
  25. Jagadis Chunder Bose, "Detector for electrical disturbances", US patent no. 755,840 (filed: September 30, 1901; issued: March 29, 1904).
  26. Greenleaf Whittier Pickard, "Means for receiving intelligence communicated by electric waves", US patent no. 836,531 (filed: August 30, 1906 ; issued: November 20, 1905).
  27. http://www.crystalradio.net/crystalplans/xximages/nsb_120.pdf
  28. http://www.crystalradio.net/crystalplans/xximages/nbs121.pdf
  29. Bondi, Victor."American Decades:1930-1939"
  30. Peter Robin Morris, A history of the world semiconductor industry, IET, 1990, ISBN 0-86341-227-0, page 15
  31. http://earlyradiohistory.us/1924cry.htm
  32. In 1924, Losev's research was publicized in several French publications:
    • Radio Revue, no. 28, p. 139 (1924)
    • I. Podliasky (May 25, 1924) (Crystal detectors as oscillators), Radio Électricité, 5 : 196-197.
    • Vinogradsky (September 1924) L'Onde Electrique
    English-language publications noticed the French articles and also publicized Losev's work:
    • Pocock (June 11, 1924)The Wireless World and Radio Review, 14 : 299-300.
    • Victor Gabel (October 1 & 8, 1924) "The crystal as a generator and amplifier," The Wireless World and Radio Review, 15 : 2ff , 47ff.
    • O. Lossev (October 1924) "Oscillating crystals," The Wireless World and Radio Review, 15 : 93-96.
    • Round and Rust (August 19, 1925) The Wireless World and Radio Review, pp. 217-218.
    • "The Crystodyne principle," Radio News, pages 294, 295, 431 (September 1924). See also the October 1924 issue of Radio News. (It was Hugo Gernsbach, publisher of Radio News, who coined the term "crystodyne".) This article is available on-line at: Radio Museum.org.
  33. Lua error in package.lua at line 80: module 'strict' not found.
  34. Lua error in package.lua at line 80: module 'strict' not found.
  35. Lua error in package.lua at line 80: module 'strict' not found.
  36. Lua error in package.lua at line 80: module 'strict' not found.
  37. 37.0 37.1 37.2 37.3 Lua error in package.lua at line 80: module 'strict' not found. on Stay Tuned website
  38. 38.0 38.1 38.2 38.3 38.4 38.5 Lua error in package.lua at line 80: module 'strict' not found.
  39. Lua error in package.lua at line 80: module 'strict' not found.
  40. Lescarboura, 1922, p. 144
  41. 41.0 41.1 41.2 Lua error in package.lua at line 80: module 'strict' not found.
  42. Marconi used carborundum detectors for a time around 1907 in his first commercial transatlantic wireless link between Newfoundland, Canada and Clifton, Ireland. Lua error in package.lua at line 80: module 'strict' not found.
  43. 43.0 43.1 43.2 43.3 43.4 43.5 43.6 43.7 43.8 Lua error in package.lua at line 80: module 'strict' not found.
  44. a list of circuits from the wireless era can be found in Lua error in package.lua at line 80: module 'strict' not found.
  45. Lua error in package.lua at line 80: module 'strict' not found. is a collection of 12 circuits
  46. Lua error in package.lua at line 80: module 'strict' not found.
  47. 47.0 47.1 47.2 47.3 Lua error in package.lua at line 80: module 'strict' not found.
  48. Lua error in package.lua at line 80: module 'strict' not found.
  49. Lua error in package.lua at line 80: module 'strict' not found.
  50. Lua error in package.lua at line 80: module 'strict' not found.
  51. Lescarboura 1922, p.100
  52. Lua error in package.lua at line 80: module 'strict' not found.
  53. Lescarboura, 1922, p. 102-104
  54. Lua error in package.lua at line 80: module 'strict' not found.
  55. Lua error in package.lua at line 80: module 'strict' not found.
  56. Hausmann, Goldsmith & Hazeltine 1922, p. 48
  57. Lua error in package.lua at line 80: module 'strict' not found.
  58. 58.0 58.1 Lua error in package.lua at line 80: module 'strict' not found.
  59. Lua error in package.lua at line 80: module 'strict' not found. on Stay Tuned website
  60. Lua error in package.lua at line 80: module 'strict' not found. on Crystal Radios and Plans, Stay Tuned website
  61. 61.0 61.1 61.2 61.3 61.4 61.5 Lua error in package.lua at line 80: module 'strict' not found.
  62. Hausmann, Goldsmith & Hazeltine 1922, p. 57
  63. Lua error in package.lua at line 80: module 'strict' not found.
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  66. Lua error in package.lua at line 80: module 'strict' not found.
  67. Lua error in package.lua at line 80: module 'strict' not found.
  68. Marx & Van Muffling (1922) Radio Reception, p.94
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  72. Lua error in package.lua at line 80: module 'strict' not found.
  73. Alley & Atwood (1973) Electronic Engineering, p. 318
  74. Marx & Van Muffling (1922) Radio Reception, p.96-101
  75. Lua error in package.lua at line 80: module 'strict' not found.
  76. Marx & Van Muffling (1922) Radio Reception, p.43, fig.22
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  78. Lua error in package.lua at line 80: module 'strict' not found.
  79. http://rileyjshaw.com/blog/the-cat's-whisker-detector/ stating, "The cat’s-whisker detector is a primitive point-contact diode. A point-contact junction is the simplest implementation of a Schottky diode, which is a majority-carrier device formed by a metal-semiconductor junction."
  80. Lua error in package.lua at line 80: module 'strict' not found.
  81. Stanley (1919) Text-book on Wireless Telegraphy, p.282
  82. 82.0 82.1 Hausmann, Goldsmith & Hazeltine 1922, pp. 60–61
  83. 83.0 83.1 Lescarboura (1922), p.143-146
  84. Stanley (1919), p. 311-318
  85. Lua error in package.lua at line 80: module 'strict' not found. on Crystal Plans and Circuits, Stay Tuned website
  86. Lua error in package.lua at line 80: module 'strict' not found.
  87. Lua error in package.lua at line 80: module 'strict' not found.
  88. Lua error in package.lua at line 80: module 'strict' not found.
  89. Lua error in package.lua at line 80: module 'strict' not found.
  90. The Principles Underlying Radio Communication (1922), p.439-440
  91. Lua error in package.lua at line 80: module 'strict' not found.
  92. 92.0 92.1 Field 2003, p.93-94
  93. Lescarboura (1922), p.285
  94. Collins (1922), p. 27-28
  95. Williams (1922), p. 79
  96. The Principles Underlying Radio Communication (1922), p. 441
  97. Lua error in package.lua at line 80: module 'strict' not found.
  98. Field (2003), p. 94
  99. Walter B. Ford, "High Power Crystal Set", August 1960, Popular Electronics
  100. 100.0 100.1 Lua error in package.lua at line 80: module 'strict' not found.
  101. Radio-Electronics, 1966, №2
  102. Lua error in package.lua at line 80: module 'strict' not found.

Further reading

External links

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